Pain and temperature processing in dementia: a clinical and neuroanatomical analysis.

Symptoms suggesting altered processing of pain and temperature have been described in dementia diseases and may contribute importantly to clinical phenotypes, particularly in the frontotemporal lobar degeneration spectrum, but the basis for these symptoms has not been characterized in detail. Here we analysed pain and temperature symptoms using a semi-structured caregiver questionnaire recording altered behavioural responsiveness to pain or temperature for a cohort of patients with frontotemporal lobar degeneration (n = 58, 25 female, aged 52-84 years, representing the major clinical syndromes and representative pathogenic mutations in the C9orf72 and MAPT genes) and a comparison cohort of patients with amnestic Alzheimer's disease (n = 20, eight female, aged 53-74 years). Neuroanatomical associations were assessed using blinded visual rating and voxel-based morphometry of patients' brain magnetic resonance images. Certain syndromic signatures were identified: pain and temperature symptoms were particularly prevalent in behavioural variant frontotemporal dementia (71% of cases) and semantic dementia (65% of cases) and in association with C9orf72 mutations (6/6 cases), but also developed in Alzheimer's disease (45% of cases) and progressive non-fluent aphasia (25% of cases). While altered temperature responsiveness was more common than altered pain responsiveness across syndromes, blunted responsiveness to pain and temperature was particularly associated with behavioural variant frontotemporal dementia (40% of symptomatic cases) and heightened responsiveness with semantic dementia (73% of symptomatic cases) and Alzheimer's disease (78% of symptomatic cases). In the voxel-based morphometry analysis of the frontotemporal lobar degeneration cohort, pain and temperature symptoms were associated with grey matter loss in a right-lateralized network including insula (P < 0.05 corrected for multiple voxel-wise comparisons within the prespecified anatomical region of interest) and anterior temporal cortex (P < 0.001 uncorrected over whole brain) previously implicated in processing homeostatic signals. Pain and temperature symptoms accompanying C9orf72 mutations were specifically associated with posterior thalamic atrophy (P < 0.05 corrected for multiple voxel-wise comparisons within the prespecified anatomical region of interest). Together the findings suggest candidate cognitive and neuroanatomical bases for these salient but under-appreciated phenotypic features of the dementias, with wider implications for the homeostatic pathophysiology and clinical management of neurodegenerative diseases.

Introduction

The frontotemporal lobar degenerations (FTLDs) are a diverse group of proteinopathies characterized by selective degeneration of distributed brain networks involving the frontal and temporal lobes. Altered processing of sensory signals is an important feature of these diseases (Bathgate ; Snowden ; Pijnenburg ; Jesso ; Omar , 2013; Rohrer ; Fletcher ; Downey ; Landqvist Waldo ; Perry ; Woolley ; Zhou and Seeley, 2014). Patients commonly fail to interpret emotional and social cues correctly (Jesso ; Omar ; Kumfor and Piguet, 2012; Zhou and Seeley, 2014) and may show obsessional attachment to particular stimuli such as sweet foods (Woolley ) or music (Fletcher ) suggesting a generic disturbance in processing reward and attributing hedonic valence (Perry ). However, several series have documented symptoms that might signify a more fundamental abnormality in coding somatosensory signals, in particular pain and temperature, by patients with FTLD (Bathgate ; Snowden ; Ahmed ). Unpleasant somatic symptoms, often with a nociceptive component (including non-specific unexplained headaches, musculoskeletal, abdominal or urogenital discomfort, vague migrating pains, chest pain and pruritus), have been described in a substantial proportion of patients with FTLD and may be early and prominent (Snowden ); such symptoms may be particularly salient in the syndromes of semantic dementia and behavioural variant frontotemporal dementia (FTD), especially with C9orf72 mutations (Landqvist Waldo ). Patients may exhibit strikingly abnormal ‘sensory behaviours’, especially reduced responsiveness to painful stimuli in behavioural variant FTD and exaggerated responses to pain in semantic dementia (Bathgate ; Snowden ). Symptoms suggesting disturbed thermoregulation have also been reported with high prevalence in behavioural variant FTD and semantic dementia (Ahmed ). Limited psychophysical evidence has suggested overall increases in pain threshold and tolerance in FTD, albeit with considerable individual variation (Carlino ).

Such reports suggest that pain and temperature responsiveness are commonly though variably altered in FTLD and are of considerable interest on both neurobiological and clinical grounds. The neuroanatomical correlates of pain processing in the healthy brain comprise a distributed network with critical hubs in thalamus and insula and somatosensory, prefrontal, anterior temporal, limbic and subcortical connections (Peyron ; Craig, 2002; Herde ; Moulton ). Temperature sensibility is mediated by a closely overlapping network (Craig, 2002; Moulton ). Together these networks have a core role in regulation of bodily homeostasis: current neurobiological formulations emphasize convergent processing of somatic and visceral pain and thermoregulatory signals as functionally interdependent aspects of interoception (Craig, 2002, 2009). Separable network components underpin sensory gating and representation (thalamus, posterior insula, somatosensory cortex), arousal and attention (thalamus, anterior cingulate), evaluative and contextual processing (anterior insula, anterior cingulate, anterior temporal cortex, amygdala, hippocampus), and programming behavioural responses (anterior cingulate, orbitofrontal and prefrontal cortices) (Greenspan and Winfield, 1992; Peyron ; Singer ; Brooks ; Höistad and Barbas, 2008; Craig, 2009; Mazzola , 2012; Isnard ; Moulton ; Meerwijk ). These networks overlap extensively with networks targeted by the pathological process in FTLD. Impaired body schema integrity has recently been demonstrated in patients with C9orf72 mutations (Downey , 2014) and may be a generic pathophysiological mechanism of somatic delusions, somatization and other neuropsychiatric symptoms in these patients, due to disruption of a core thalamo-cortico-cerebellar network (Mahoney ; Lee ); involvement of thalamus, in particular, has emerged as a consistent and early signature of this mutation subgroup (Rohrer ). Impaired appraisal of salient sensory objects and events is integral to the clinical syndromes of semantic dementia and behavioural variant FTD, notably in association with right anterior temporal lobe atrophy (Bathgate ; Snowden ; Chan ). Considered together, this evidence suggests that pain and temperature pathophysiology may link brain network disintegration with clinical symptoms in these diseases. However, in contrast with the well-characterized central pain syndromes attending focal lesions of thalamocortical circuitry (Schmahmann and Leifer, 1992; Blomqvist ; Borsook, 2012), the phenomenology of pain and temperature processing and their neuroanatomical bases have not been studied in detail in FTLD. Moreover, altered experience of pain and temperature might be predicted in other neurodegenerative diseases that disrupt the integrity of distributed networks that process pain and temperature (Borsook, 2012). A notable test case is Alzheimer’s disease. Limited available information suggests that sensory encoding and perception of pain are retained in Alzheimer’s disease, at least in early to moderate stage disease, with engagement of a similar central nociceptive network to healthy older individuals (Cole ); however, patients’ pain tolerance has been variously reported as unaltered, increased or diminished (Cole , 2011; Borsook, 2012; Jensen-Dahm ) and semantic processing of pain concepts may also be diminished (Oosterman ).

Here we addressed these issues in cohorts of patients representing the major syndromes of FTLD and typical Alzheimer’s disease. Symptoms suggesting altered pain and temperature processing were characterized using a semi-structured pro forma administered to patients’ caregivers. Structural neuroanatomical correlates of these symptoms were assessed using voxel-based morphometry (VBM) of patients’ brain magnetic resonance images. We hypothesized that pain and temperature symptoms would be over-represented in behavioural variant FTD and semantic dementia versus progressive non-fluent aphasia (PNFA) and Alzheimer’s disease, and more specifically, in patients with C9orf72 mutations versus other disease groups; and that behavioural variant FTD and semantic dementia have overlapping but differentiable symptom profiles characterized by blunted versus heightened pain and temperature responsiveness, respectively. We further hypothesized that pain and temperature symptoms in the FTLD cohort and in Alzheimer’s disease would be associated with grey matter atrophy in the distributed network previously implicated in pain and temperature processing in the healthy brain. More specifically, we hypothesized an association of insular atrophy with symptoms across syndromes (Peyron ; Craig, 2002; Zhou and Seeley, 2014); and partly separable neuroanatomical associations, targeting thalamus in C9orf72 mutations, more anterior cortical regions in other FTLD subgroups and more posterior somatosensory cortical association areas in Alzheimer’s disease (Cole ; Chan ; Downey ; Lee ).

Materials and methods

Patient characteristics

Fifty-eight patients with FTLD (25 female, aged 52–84 years) and 20 patients with Alzheimer’s disease (eight female, aged 53–74 years) were assessed consecutively over a 3-year interval via a tertiary Cognitive Disorders Clinic. All fulfilled consensus diagnostic criteria for a syndrome of FTLD (Gorno-Tempini ; Rascovsky ) (behavioural variant FTD, n = 21; semantic dementia, n = 17; PNFA, n = 20) or for Alzheimer’s disease led by decline in episodic memory (Dubois ). The syndromic diagnosis was supported in each case by detailed clinical and neuropsychological evaluation following a standard protocol referenced to a historical, age-matched healthy control group (Table 1) and further corroborated by CSF and brain amyloid PET imaging findings (ratio of total tau: amyloid-β1-42 levels >1 in 14/14 Alzheimer’s disease cases and <0.8 in 13/13 FTLD cases; florbetapir PET-negative for amyloid deposition in 7/7 FTLD cases for which data were available). All patients had MRI profiles of regional brain atrophy concordant with their clinical diagnosis; no patient had radiological evidence of significant or strategic vascular damage. Genetic screening revealed 11 patients with a pathogenic mutation (six C9orf72; five MAPT). All patients with a genetic mutation presented with behavioural variant FTD apart from one patient with a C9orf72 expansion who presented with PNFA.

Table 1

General demographic and neuropsychological data for patient subgroups

Characteristic	FTLD: pain / temperature		AD: pain / temperature		Healthy controlsa
	Symptoms	No symptoms	Symptoms	No symptoms
General demographics
n: total (F:M)	31(10:21)b	27 (15:12)	9 (2:7)c	11 (6:5)	50 (23:27)
n: syndromes bvFTD / SD / PNFA	15/ 11 / 5	6 / 6 / 15	NA	NA	NA
n: no mutation / C9orf72 / MAPT	24 / 6 / 2	23 / 0 / 3	NA	NA	NA
Age (years)	65.4 (52–84)	64.8 (47–80)	63.8 (53–71)	65 (57–74)	67.5 (54–80)
Education (years)	13.9 (11–20)	15.2 (11–21)	13 (11–17)	15 (12–17)	15.2 (10–18)
Symptom duration (years)	6.5 (3–21)	4.8 (2–18)	5 (2–8)	5.5 (4–9)	NA
MMSE	21.1 (4–30)	21.9 (1–30)	20 (13–25)	22.5 (14–29)	29.6 (28–30)
MRI profilesd
Temporal lobe atrophy (L:R:symm)	22(8:5:9)	16(12:1:3)	6(0:0:6)	9(0:0:9)	NA
Frontal lobe atrophy (L:R:symm)	10(3:2:5)	11(6:1:4)	0	0	NA
Parietal lobe atrophy (L:R:symm)	3(1:0:2)	0	2(0:0:2)	1(0:0:1)	NA
General intellect
Verbal IQ	76 (40–126)	78 (55–119)	86 (55–115)	93 (55–120)	120 (101–137)
Performance IQ	91 (65–136)	101 (69–134)	81 (59–125)	92 (63–119)	115 (84–141)
Episodic memory
RMT words (/50)	34 (20–49)	37 (18–47)	29 (17–42)	32 (24–50)	48 (39–50)
RMT faces (/50)	31 (24–50)*	36 (25–47)	32 (18–45)	39 (24–46)	43 (30–50)
Executive function
Stroop word (90 s)	35 (16–90)	39 (18–90)	43 (17–79)	36.6 (17–58)	22.7 (15–53)
Stroop inhibition (180 s)	100 (48–180)	105 (48–180)	143 (42–180)	101.4 (30–180)	57.6 (35–103)
Digit span reverse (/12)	3.7 (0–7)	4 (0–7)	3 (1–6)	3.6 (1–7)	5 (3–7)
Semantic processing
BPVS (/150)	98 (2–149)	118 (8–149)	126 (76–146)	132 (52–147)	147 (137–150)
Synonyms (/50)	34 (12–50)b	38 (20–49)	41 (30–49)	47.5 (46–49)	48 (36–50)
Visuospatial
VOSP object decision (/20)	16 (8–20)	17 (10–20)	16 (10–18)	15 (7–19)	18 (12–20)

Mean (range) data are shown unless otherwise indicated and maximum scores on neuropsychology tests are also indicated in parentheses. Significant differences (P < 0.05) between patients and controls are in bold.

aHistorical age-matched group.

bFive patients with altered pain responses only, 13 with altered temperature responses only, 13 with both (see Table 2).

cSix patients with altered temperature responses only, three with alteration of both pain and temperature responses.

dBlinded visual rating of brain MRI scans (L:R:symm, number of cases with relatively focal lobar atrophy predominantly left-sided, right-sided or relatively symmetric; note lobar involvement not mutually exclusive).

*Significantly (P < 0.05) different from non-symptomatic patients with FTLD.

AD = syndrome of Alzheimer’s disease led by decline in episodic memory; BPVS = British Picture Vocabulary Scale; bvFTD = behavioural variant FTD; F = female; M = male; MMSE = Mini-Mental State Examination score; NA = not applicable; RMT = Recognition Memory Test; SD = semantic dementia; temp = temperature; VOSP = Visual Object and Space Perception battery.

Table 2

Detailed description of the symptomatic patient cohort

Syndromic diagnosis	n	MRI profile: focal atrophya			Symptom category	Response shift
		TL	FL	PL
		L/R/symm	L/R/symm	L/R/symm	P/T/both	inc/dec/bothb
Behavioural variant FTD	15	1/2/5	2/2/3	1/0/0	4/7/4	6/6/3
Semantic dementia	11	6/2/3	0	0/0/1	1/3/7	8/1/2
PNFA	5	1/1/1	1/0/2	0/0/1	0/3/2	3/0/2
Alzheimer’s disease	9	0/0/6	0	0/0/2	0/6/3	7/0/2

*Blinded visual rating of brain MRI scans (L:R:symm, number of cases with relatively focal lobar atrophy predominantly left-sided, right-sided or relatively symmetric; note lobar involvement not mutually exclusive).

bVariably increased or decreased responsiveness within or between modalities.

dec = decreased; FL = frontal lobe atrophy; inc = increased; L = left; N = normal; P = symptoms of altered pain experience; PL = parietal lobe atrophy; R = right; symm = relatively symmetric; T = symptoms of altered temperature experience; TL = temporal lobe atrophy.

Patients’ caregivers completed a semi-structured questionnaire designed to identify symptoms suggesting altered pain or temperature processing (altered experience of pain or temperature) developing since the onset of their illness (Supplementary Table 1). This questionnaire recorded caregiver descriptions of patients’ symptoms and initially sought to capture any unexplained unpleasant physical symptoms more generally, before focusing explicitly on altered behavioural responses to pain or temperature variations. Questionnaire data were analysed off-line to determine the nature of any alteration in pain or temperature responsiveness and its directionality (increased versus decreased), based on caregiver descriptions of patients’ overt verbal and non-verbal behaviours. Chi-square tests were used to compare categorical differences in symptom prevalence and linear regression was used to compare differences in background demographic and neuropsychological measures between groups. In addition, we assessed for any correlation between pain and temperature symptoms and any alteration in hedonic processing in the domains of music and environmental sounds, as previously recorded for this patient cohort (Fletcher ).

All participants gave informed consent to be involved in the study, which was approved by the local institutional ethics committee in accordance with the Declaration of Helsinki.

Brain MRI acquisition and analyses

At the time of questionnaire data collection each patient underwent volumetric brain MRI on a 3.0 T Siemens scanner using a 32-channel phased-array head coil. A sagittal 3D magnetization prepared rapid gradient echo T1-weighted volumetric MRI (echo time/repetition time/inversion time 2.9/2200/900 ms, dimensions 256 × 256 × 208, voxel size 1.1 × 1.1 × 1.1 mm) was acquired. In all cases, volumetric scans were assessed visually in all planes to ensure adequate coverage and to exclude artefacts or significant motion.

To assess any relation between individual brain atrophy profile and development of pain and temperature symptoms, each patient’s brain magnetic resonance scan was reviewed by two experienced cognitive neurologists (P.D.F., J.D.W.) while blinded to symptomatic and clinical syndromic status. In each case, the presence of relatively focal brain atrophy (disproportionate to more diffuse background atrophy) and the direction of any cerebral hemispheric asymmetry on visual inspection were recorded for the frontal, temporal and parietal lobes. Any apparent right:left directionality of atrophy was assessed for each lobar region using chi-square tests.

Preprocessing of patients’ brain magnetic resonance images for VBM was performed using New Segment (Ashburner and Friston, 2005) and the DARTEL (Ashburner, 2007) toolbox of SPM8 (www.fil.ion.ucl.ac.uk/spm) running under Matlab7.0®. Segmentation, normalization and modulation of grey and white matter images were performed using default parameter settings. Images were smoothed using a Gaussian full-width at half-maximum of 6 mm. To adjust for individual differences in global grey matter volume during subsequent analysis, total intracranial volume was calculated for each participant by summing grey matter, white matter and CSF volumes following segmentation of all three tissue classes. A study-specific group mean template brain image was created by warping all native space whole-brain images to the final DARTEL template and calculating the average of the warped brain images.

Voxel intensity (grey matter volume) was modelled for the combined FTLD cohort and for the Alzheimer’s disease cohort: firstly, as a function of presence versus absence of any symptoms suggesting altered pain or temperature processing; and as a function of presence versus absence of symptoms for pain and for temperature separately. Participant age, total intracranial volume, Mini-Mental State Examination score (as a global measure of disease severity) and syndromic group membership (where relevant) were included as covariates of no interest in the models. In addition, in light of recent evidence suggesting a distinct pathophysiological signature of C9orf72-associated FTLD (Downey ; Lee ), we performed a subanalysis of the symptomatic FTLD cohort contrasting patients with and without C9orf72 mutations. To help protect against voxel drop-out due to potentially marked local regional atrophy, a customized explicit brain mask was applied based on a specified ‘consensus’ voxel threshold intensity criterion (Ridgway ) whereby a voxel was included in the analysis if grey matter intensity at that voxel was >0.1 in >70% of participants (rather than in all participants, as with the default SPM8 mask).

Statistical parametric maps of regional grey matter volume correlating with pain and temperature symptoms were assessed using two prescribed criteria, each thresholded at P < 0.05 after family-wise error (FWE) correction for multiple voxel-wise comparisons. Maps were first assessed after correction over the whole brain volume, to determine any associations that emerged without taking the evidence of previous studies into account. Maps were next assessed after correction within a regional small volume of interest, taking account of previous evidence and our specific anatomical hypotheses: this single anatomical small volume combined structures in both cerebral hemispheres consistently identified as critical for interoceptive and homeostatic processing of pain and temperature in the healthy brain, namely, insular cortex and thalamus (Lenz ; Davis ; Craig ; Brooks ; Kim ; Isnard ; Mazzola ). Relevant anatomical subregions were customized from the Oxford/Harvard brain maps in FSLview v3.1 (Desikan ; Jenkinson ) to fit the group mean template brain image. The overall distribution of grey matter atrophy in key disease subgroups with and without pain and temperature symptoms was assessed relative to healthy controls in a separate VBM analysis (further details in the online Supplementary material).

Results

Analysis of pain and temperature symptoms

Characteristics of the patient cohort are summarized in Table 1 and a detailed analysis of symptoms is presented in Table 2; extracts from caregiver questionnaire reports for individual patients are presented in Supplementary Table 2.

Symptoms suggesting abnormalities of pain and/or temperature processing were reported in 31/58 patients with FTLD (53% of the whole FTLD cohort) and in 9/20 patients with Alzheimer’s disease (45% of the Alzheimer’s disease cohort). In both FTLD and Alzheimer’s disease cohorts, altered responses to temperature variations were more frequently reported than altered responses to pain. While patients with FTLD (13/31 cases, 41%) and Alzheimer’s disease (3/9, 33%) commonly had altered responses both to pain and temperature, only patients with FTLD (5/31 cases, 16%) had altered pain responses alone. Within the FTLD cohort, symptoms suggesting altered pain or temperature processing were statistically significantly more common in the behavioural variant FTD group (15/21 cases, 71%) and semantic dementia group (11/17 cases, 65%) than in the PNFA group (5/20 cases, 25%: P < 0.05 all comparisons): accordingly, behavioural variant FTD and semantic dementia phenotypes were relatively over-represented in the symptomatic FTLD subgroup (Table 1). Of the genetic FTLD subgroups, patients with C9orf72 mutations were over-represented in the symptomatic subgroup, reporting symptoms suggesting altered pain or temperature processing in all (6/6) cases; whereas these symptoms were recorded less frequently (2/5 cases) for patients with MAPT mutations.

Caregiver reports (Supplementary Table 2) revealed a diverse phenomenology of altered pain and temperature experience among patients in the symptomatic cohort. Pain symptoms were variably reported as arising from the external environment or from within the patient’s own body; while temperature symptoms were mainly described as subjective discomfort relative to the ambient environment and only occasionally referred to thermal touch per se. Symptoms varied widely in intensity and frequency. Both increased responsiveness and decreased responsiveness to pain and temperature variations were described, as well as responses that were variably increased or decreased within or between modalities. Within the temperature modality, patients more often developed a dislike of cold (rather than warm) environments. The directional preponderance of altered pain and temperature responsiveness varied between syndromic groups: within the behavioural variant FTD group, decreased responsiveness and increased responsiveness to pain and temperature variations were equally frequent (each reported in six cases, 40%); whereas increased responsiveness was more commonly described within the semantic dementia group (8/11 cases, 73%), the PNFA group (3/5 cases, 60%) and the Alzheimer’s disease group (7/9 cases, 78%; see Table 2). More complex bidirectional shifts in pain and temperature responses were also described in all syndromic groups. The small C9orf72 mutation subgroup described symptoms similar to those reported for the cohort as a whole (Supplementary Table 2).

When neuropsychological profiles in the patient subgroups within the FTLD and Alzheimer’s disease cohorts were compared according to the presence or absence of pain and temperature symptoms, the symptomatic FTLD group showed significantly (P < 0.01) greater impairment of face memory than the non-symptomatic FTLD subgroup; the subgroups within each disease cohort were otherwise similar overall (Table 1). Thyroid function (available for 66/78 patients including 34/40 patients with pain and temperature symptoms) was normal in all cases assessed. Three patients in the FTLD cohort with pain and temperature symptoms underwent nerve conduction studies, which were normal in all cases. The presence of pain and/or temperature symptoms was positively correlated with altered liking for music (P = 0.03) but not environmental sounds (P = 0.8).

Neuroanatomical correlates of altered pain and temperature processing

Visual review of individual patient MRI scans (summarized in Tables 1 and 2) revealed an over-representation of cases with relatively focal temporal lobe atrophy in the subgroup of patients with FTLD and pain and temperature symptoms in comparison to the group without such symptoms. In particular, right-sided temporal lobe atrophy was more common in the subgroup of patients with pain and temperature symptoms than the subgroup without symptoms (case ratio 5:1; see Table 1). However, this apparent disproportion was not statistically significant (P > 0.05). Focal temporal lobe atrophy was frequent in all three FTLD syndromes within the symptomatic cohort but concentrated (as anticipated) in the semantic dementia subgroup. These findings were further corroborated in the VBM analysis mapping overall grey matter atrophy profiles in FTLD subgroups with and without pain and temperature symptoms versus healthy controls (Supplementary Fig. 1 and Supplementary Table 3). Disproportionate temporal lobe atrophy was also frequent in patients with Alzheimer’s disease and pain and temperature symptoms; however, in contrast to the FTLD cases, none of these Alzheimer’s disease patients exhibited asymmetric temporal lobe involvement nor was there any temporal lobe predilection for symptomatic versus non-symptomatic Alzheimer’s disease cases.

Regional grey matter correlates of pain and temperature symptoms from the VBM analysis are summarized in Table 3 and statistical parametric maps are shown in Fig. 1. No grey matter correlates of pain and temperature symptoms were identified at the prescribed corrected significance threshold (P < 0.05FWE) at the level of the whole brain. However, within the combined FTLD cohort, the presence of any alteration in pain or temperature responsiveness was significantly associated with atrophy of right mid insula (and borderline significant also for right posterior insula) when thresholded at P < 0.05FWE after correction within the prespecified anatomical region of interest; no significant grey matter associations were identified for pain symptoms or for temperature symptoms separately, at the prescribed threshold. In the separate VBM subanalysis of patients with C9orf72 expansions contrasted with other FTLD patients showing altered pain or temperature responses (Table 3 and Fig. 1), symptoms due to C9orf72 mutations were significantly associated with atrophy of right posterior thalamus (and borderline significant also for left posterior thalamus; P < 0.05FWE within the prespecified anatomical region of interest). No other grey matter associations were identified at the prescribed significance threshold.

Table 3

Voxel-based morphometric correlates of altered pain and temperature processing in FTLD

Grey matter association	Brain region	Side	Cluster (voxels)	Peak (mm)			Z-score	P-value
				x	y	z
All FTLD	Mid insula	R	227	40	−1	0	4.37	0.02
	Posterior insula	R	105	39	−18	−2	4.05	0.055
C9orf72 mutations	Posterior thalamus	R	66	20	−24	3	3.73	0.03
		L	115	−18	−25	1	3.55	0.055

Significant regional correlates of altered pain and temperature processing (grey matter atrophy associated with any symptoms suggesting altered responsiveness to pain and/or temperature) are based on contrasts over the whole frontotemporal lobar degeneration (FTLD) cohort (all symptomatic versus all asymptomatic patients) and in patients with C9orf72 mutations (all symptomatic versus symptomatic patients without C9orf72 mutations). Associations are reported after correction for multiple voxel-wise comparisons within the prespecified anatomical small volume of interest; all significant clusters >40 voxels are shown and peak (local maximum) coordinates are in MNI standard stereotactic space (see also Fig. 1 and further details in Supplementary Fig. 2).

Figure 1

Statistical parametric maps (SPMs) showing regional grey matter atrophy significantly associated with altered pain and/or temperature responsiveness in the FTLD cohort. See also Table 3. SPMs are based on the contrast between patient subgroups with and without symptoms in the combined cohort (All FTLD, top) and in patients with C9orf72 mutations (C9orf72; all symptomatic) versus symptomatic patients without C9orf72 mutations (bottom). SPMs are thresholded for display purposes at P < 0.001 uncorrected for multiple comparisons over the whole brain and rendered on sections of a group mean T1-weighted magnetic resonance brain template image in MNI standard space; coordinates (mm) of the plane of each section are indicated and the right hemisphere is shown on the right of the coronal sections and the axial section (bottom right, magnified to show thalamic anatomy). Z-scores for the SPMs are scaled according to the colour bar.

To identify any less robust but potentially relevant neuroanatomical associations of pain and temperature symptoms in the patient cohort, we performed a separate post hoc exploratory analysis of the VBM data thresholded more leniently at P < 0.001 uncorrected for multiple voxel-wise comparisons over the whole brain. At this more lenient threshold, additional regional grey matter correlates were observed (Supplementary Fig. 2 and 3). Pain and temperature symptoms in the combined FTLD cohort and in the subgroup not associated with C9orf72 mutations were additionally associated with atrophy of right anterior temporal cortex; while temperature symptoms (but not pain symptoms) in the FTLD cohort were associated with atrophy of right mid-insula (Supplementary Fig. 2). Pain and temperature symptoms within the smaller Alzheimer’s disease cohort were associated with grey matter atrophy in left angular gyrus (Supplementary Fig. 3) using this relaxed criterion.

Discussion

Here we have shown that altered experience of pain and temperature is common in the major dementia syndromes. Altered behavioural responses to both pain and temperature were frequently reported but more often reported for temperature than pain. In line with our prior hypotheses and previous work (Bathgate ; Snowden , 2013; Pijnenburg ; Mahoney ; Ahmed ; Downey ; Landqvist Waldo ), certain syndromic signatures were identified. Pain and temperature symptoms were commonly described across FTLD syndromes, exhibited by the majority of patients with behavioural variant FTD and semantic dementia and most frequently in the molecular subtype represented by C9orf72 mutations. Patients with Alzheimer’s disease exhibited similar symptoms in a somewhat lower proportion (45%) of cases. The directionality of symptoms (heightened versus diminished responses to pain and temperature) varied across the cohort but was also modulated by syndrome: increased responsiveness to pain or temperature variations was most often reported in the semantic dementia, PNFA and Alzheimer’s disease groups whereas decreased responsiveness was most often associated with behavioural variant FTD, again consistent with previous evidence (Bathgate ; Snowden ; Carlino ). Occurrence of symptoms was not simply attributable to disease severity or other demographic or general neuropsychological factors. Though not quantified here, the reported intensity and frequency of symptoms varied widely among individuals in each syndromic group.

Pain and temperature symptoms were frequently accompanied by focal (and particularly, right-sided) temporal lobe atrophy in individual patients with FTLD, as anticipated from previous work and consistent with the more severe face processing deficit in this FTLD subgroup (Snowden ; Chan ; Omar ). However, asymmetric temporal lobe atrophy was not a sine qua non for development of such symptoms, as illustrated by the Alzheimer’s disease cases. In line with these findings and with previous studies in the healthy brain (Peyron ; Craig, 2002; Singer ; Henderson ; Herde ; Isnard ; Borsook, 2012; Moulton ), a VBM group analysis of patients’ brain MRIs delineated a distributed network of brain regions where atrophy was associated with altered responsiveness to pain or temperature. The most robust network correlates of pain and temperature symptoms comprised right-lateralized grey matter areas in mid and posterior insula in the combined FTLD group and bilateral posterior thalamus in the C9orf72 mutation group.

These findings substantiate current formulations of the neural organization of central somatosensory and homeostatic signal processing (Craig, 2002, 2009; Borsook, 2012; Preusser ). Peripheral somatic and visceral sensory afferents conveying pain and thermal information relay via postero-lateral thalamic nuclei to somatosensory cortex (Brodmann area 3a) and dorsal posterior insula (Craig, 2002). While primary somatosensory cortex may process tactile events (Preusser ), classical models emphasizing somatosensory labelled lines have been incorporated by current models that emphasize the intimate association of pain and thermal information and their integration as joint aspects of interoception, salient sensory phenomena that are potentially critical for signalling body homeostasis (Craig, 2002, 2009). The posterior insula is a central network hub for integration of these homeostatic signals to map an interoceptive ‘image’ of body state (Craig, 2002). Focal lesions of posterior thalamus and posterior insula are well known to produce central pain syndromes and microstimulation of these regions may produce pain and thermal sensations (Blomqvist ; Mazzola , 2012; Sprenger ). The thalamo-insular network plays a broader role in integrating external and interoceptive sensory signals to generate a coherent body schema that defines bodily integrity and agency in relation to the environment (Lenz ; Davis ; Banzett ; Craig , 2002, 2009; Critchley , 2011; Brooks ; Critchley, 2005; Henderson ; Seeley , , 2009; Corbetta ; Sridharan ; Bjornsdotter ; Mazzola , 2012; Menon and Uddin, 2010; Beissner ).

Both insula and thalamus are involved by the pathological process in FTLD (Chow ; Zhou ; Garibotto ). In this regard, it is particularly pertinent that posterior thalamic atrophy emerged here as a signature of pain and temperature symptoms with C9orf72 mutations. While the clinical and neuroanatomical phenotypic spectrum of C9orf72-associated disease is protean, neuropsychiatric disturbances are often early and prominent and may be underpinned by disintegration of a large-scale cortico-thalamo-cerebellar brain network (Downey ; Mahoney ; Snowden , 2013; Takada and Sha, 2012; Whitwell ; Lee ; Rohrer ). Deranged body schema processing is a candidate pathophysiological mechanism linking network pathology with clinical features in C9orf72 mutations (Downey ), and disturbed pain processing due to thalamic dysfunction might be a critical signal of this more general impairment in representing bodily integrity. It would be intriguing if this clinical phenotype had a specific micro-anatomical marker (Blomqvist ). Pathological data have demonstrated heavy thalamic involvement in a series of C9orf72 mutation cases reporting a high frequency of unexplained somatic and visceral pains during life (Landqvist Waldo ). Although precise localization was not possible in this study, the posterior thalamic correlate identified in the C9orf72 mutation group here closely approximates several potentially relevant thalamic subregions. These include pulvinar, which may regulate cortical ‘set’ for interpreting painful stimuli (Shipp, 2003); and the posterior portion of the ventral medial thalamic nucleus, which is likely to serve as a dedicated spinothalamocortical relay for pain and temperature sensations and may play a fundamental role in signalling physiological body states (Blomqvist ).

Caution is needed in interpreting the additional neuroanatomical correlates identified in this study, as these were exploratory and substantially less statistically robust. However, involvement of right anterior temporal cortex in the FTLD group (and more particularly, the subgroup of patients without C9orf72 mutations) here was corroborated both by inspection of individual magnetic resonance brain images and the relaxed VBM analysis, and chimes with previous evidence implicating this region in non-verbal sensory semantic (including pain and somatic) processing (Chan ; Goll ; Omar , 2013; Hsieh ). Unpleasant somatic and visceral sensory experiences occur with focal damage involving this region (Naga ; Erickson ), while anterior temporal lobe dysfunction associated with migraine enhances thalamo-cortical connectivity (Moulton ). The temporal lobe may play a key role in contextualizing unpleasant sensory experience by linking these to other data on current bodily state, previous autobiographical experiences and stored conceptual (including social normative) knowledge (Rankin ; Zahn ; Aminoff ; Irish ) and by engaging a distributed anterior fronto-temporal appraisal network (Guo ; Zhou and Seeley, 2014). Degradation of this contextualizing function might preclude programming of a coherent, organized behavioural response to pain and temperature variations. The critical linkage of anterior temporal mechanisms with interoceptive processing networks is likely to be mediated via an integrative hub in mid-insular cortex (Craig, 2009), which emerged as a separate neuroanatomical correlate of altered pain and temperature responsiveness here. This region may be involved in generating subjective psychological states via projections to anterior insula, anterior cingulate, orbitofrontal and prefrontal cortices and in programming coherent autonomic effector responses (Craig, 2002, 2009; Grecucci ; Zhou and Seeley, 2014). This in turn suggests a brain substrate for autonomic dysregulation in FTLD (Ahmed ).

With a similar caveat regarding interpretation of uncorrected data, VBM analysis of the present Alzheimer’s disease cohort revealed a distinct cortical correlate of pain and temperature symptoms in inferior parietal cortex. This cortical region has been implicated in processing pain and in particular, in reorienting brain activity between resting ‘default mode’ and active attention to salient stimuli (Kucyi ; Bray ). Moreover, the region is a core target of pathology in Alzheimer’s disease (Warren ) and may be involved in a range of behavioural features in this disease that remain incompletely characterized. These Alzheimer’s disease-associated behavioural changes include anxiety and hyper-emotionality, features that also typically develop in chronic pain syndromes (Sturm ; Kucyi ; Pujol ). Aberrant activity of temporo-parietal cortex in Alzheimer’s disease might disrupt processing of interoceptive signals, both by amplifying ruminative awareness of body states via the default mode network and by gating activity in insula and anterior networks that reciprocally interact in evaluating salient stimuli (Grecucci ; Letzen ; Zhou and Seeley, 2014). The relative prominence of temperature (relative to pain) symptoms in the Alzheimer’s disease cohort here supports this interpretation, as under most circumstances thermal comfort or distress reflects the degree of perceived mismatch between one’s own body temperature and the environment; temperature sensibility might therefore be regarded as a probe of interoceptive signal processing par excellence (Craig, 2002).

Our focus on behaviourally relevant symptoms underlines several challenges in studying patients’ experience of pain and temperature. As conceptualized in contemporary neurobiological models (Craig, 2002, 2009) and illustrated by the present behavioural data, these are complex psychological constructs: alteration in a patient’s responsiveness to pain or temperature variations might reflect altered awareness, tolerance, motivation, behavioural organization or some interaction of these, all potentially dissociable processes. Informant-derived data are subject to bias: caregivers may be more likely to report patients’ behaviour or verbal output where these are heightened rather than attenuated, while certain modalities (such as non-painful thermal touch) are intrinsically less accessible to such reporting. In a number of cases, complex or bidirectional shifts in patient behaviour were described; the attempt to assign a direction to behavioural change is particularly problematic in the case of temperature processing, which might, in principle, reflect altered sensitivity to external heat, cold or both relative to own body temperature. Moreover, structural neuroanatomical correlation using VBM is a rather blunt instrument for investigating such complex network-based processes. In addition to any direct association with atrophy profile, relevant disease effects are likely to reside in connectivity alterations among network elements that are not captured on VBM, perhaps accounting for the absence here of disease effects in anterior cingulate or orbitofrontal regions that might have been anticipated a priori (Craig, 2002; Zhou and Seeley, 2014). On the other hand, VBM can identify brain substrates that are critical in the generation of symptoms.

Taking the above caveats into account, the present behavioural, MRI and VBM data together allow certain conclusions to be drawn about the breakdown of brain organization for pain and temperature processing in these neurodegenerative diseases. The processing of pain and temperature entails the transformation of sensory data into a complex experiential construct via hierarchical and integrative processing over a series of cortical relays: these stimuli are of fundamental biological significance (demanding high fidelity decoding) and at the same time, richly invested with subjective emotional, mnestic and semantic associations (demanding contextual editing and interpretation). As such, pain and temperature provide a paradigmatic illustration of a key principle of cortical neurobiology (Mesulam, 1998; Craig, 2002, 2009) and an ideal probe of large-scale brain network operations in neurodegenerative disease (Zhou and Seeley, 2014). The present evidence suggests a model for synthesizing neurodegenerative disease effects on these cortical operations that is consistent both with data from normal neurophysiological and functional neuroimaging work and the effects of focal brain lesions (Craig, 2002, 2009; Borsook, 2012). According to this synthesis (Fig. 2), C9orf72 mutations target early encoding of pain and temperature signals at the level of thalamo-cortical circuitry, accounting for the high proportion of cases reporting relevant symptoms here; while behavioural variant FTD more generally disrupts the relay of body state information from posterior insula and its integration with hedonic and environmental context in mid insula and more anterior regions. This interpretation allows for either abnormally reduced or abnormally increased subjective awareness of homeostatic signals, based on the extent to which network activity is interrupted or continues to transfer noisy signals (a mechanism potentially analogous to pain asymbolia following focal insular lesions: Berthier ; Masson ). Such noisy processing might involve degraded temporal scheduling of salient sensory and emotional signals, a key function attributed to anterior insula that is vulnerable in FTLD (Wiener and Coslett, 2008; Craig, 2009; Henley ). More anterior insular regions are also targeted in PNFA, providing a candidate locus for altered homeostatic awareness in this syndrome (Seeley ). Degeneration of anterior temporal lobe mechanisms in semantic dementia impairs contextual processing of minor discomforts via the linkage to mid insula, resulting in aberrant ‘over-valuation’ (decreased tolerance) of such stimuli; while temporo-parietal cortical damage in Alzheimer’s disease leads to aberrant salience coding of homeostatic signals, perhaps via abnormally enhanced gating of interoceptive information between the default mode network and anterior salience network (Zhou and Seeley, 2014).

Figure 2

A schematic synthesis of the effects of dementia syndromes on pain and temperature processing. Based on present data and current formulations of central homeostasis (; ; ; . Ellipses indicate core components of the homeostatic processing network, rectangles indicate linked brain regions that modulate processing of homeostatic signals and arrows signify predominant direction of information flow; anatomical regions are labelled alongside their putative roles in the processing hierarchy (grey filled ellipses) and dementia syndromes are labelled (italics) with grey crosses indicating the major locus of dysfunction in that syndrome. According to the proposed synthesis, C9orf72 mutations target early encoding of pain and temperature signals in thalamo-cortical circuitry; behavioural variant FTD disrupts the relay of body state information from posterior insula and both behavioural variant FTD and PNFA degrade its contextual integration in mid insula and more anterior regions; semantic dementia degrades anterior temporal lobe mechanisms that evaluate stimulus context; and temporo-parietal cortical damage in Alzheimer’s disease leads to abnormally enhanced gating and aberrant salience coding of homeostatic signals. Besides interruption of signalling pathways, degraded (e.g. temporally dysregulated) information flow may also contribute to network dysfunction (Craig, 2009). ACC = anterior cingulate cortex; AD = Alzheimer’s disease; ant = anterior; bvFTD = behavioural variant FTD; OFC = orbitofrontal cortex; post = posterior; SD = semantic dementia; TL = temporal lobe; TPJ = temporo-parietal junction.

This model does not exclude the possibility of additional loci (for example, spinal and brainstem pathways) at which neurodegenerative pathologies might degrade pain and temperature signals, with potential consequences for cortical elaboration of these signals (Braak ; Olausson ). However, the cerebral regions implicated in altered pain and temperature processing here overlap closely with regions previously implicated in social cognition, underlining the close coupling of homeostatic and social signal processing and their joint vulnerability in disease states (Craig, 2009; Grecucci ; Zhou and Seeley, 2014). Related phenomena such as social touch (the human analogue of grooming behaviour) are likely to share this brain circuitry and may contribute to deficits of interpersonal awareness in FTLD and other dementias (Craig, 2009). It is increasingly recognized that neurodegenerative diseases disrupt the hedonic valuation of a range of sensory signals. Besides pain and temperature, this spectrum includes signals related to eating and satiety (Whitwell ; Woolley ), music and other complex sounds (Fletcher , 2015) and somatosensory boundaries (Downey , 2014). It is therefore of interest that homeostatic symptoms in the present patient cohort were correlated with altered hedonic valuation of music. This work has demonstrated neural networks that are engaged jointly by these diverse phenomena and reaffirms the primacy of the thalamo-insular linkage in regulating the interface between homeostatic and environmental contingencies, reward and punishment (Craig, 2002, 2009; Perry ; Zhou and Seeley, 2014). Furthermore, pain like other signals in this spectrum is a crucial basis for empathy and understanding of others’ mental states, suggesting a mechanism for co-opting this same brain circuitry to represent selves other than one’s own. Such ‘mentalizing’ activity been proposed as the evolutionary driver for music (Clark ) and its disruption is an essential harbinger of many dementias (Rankin ; Sturm ).

From a clinical perspective, the present work provides a framework for understanding an important category of symptoms that has been under-emphasized in neurodegenerative disease. Our findings underline the prevalence of pain and temperature symptoms across the FTLD spectrum and suggest a syndromic preponderance characterized by blunted versus heightened responsiveness to pain and temperature signals in behavioural variant FTD and semantic dementia, respectively. This syndromic association in turn may suggest a candidate mechanism for the somatization, hypochondriasis and abnormal illness behaviour that these patients frequently exhibit, particularly in the setting of focal right temporal lobe atrophy (Chan ): bodily sensations divested of contextual meaning might plausibly drive such behaviours, particularly if compounded by deficits of social comportment (Rankin ; Zahn ; Irish ). Prominent pain and temperature alterations may constitute a clinical signature of Corf72 mutations. Perhaps more surprisingly, our findings suggest that similar symptoms (particularly affecting thermoregulatory signals) are not uncommon in patients with Alzheimer’s disease and have probably been under-recognized. Aside from any potential value in diagnosing dementia syndromes, improved understanding of patients’ experience of pain and temperature holds clear practical implications for management. The present findings go beyond the simple assumption that cognitive impairment hampers communication of distress—the data suggest that underlying brain mechanisms of pain and temperature processing may be altered in dementia. Patients with dementia may be at increased risk of undetected illness or injury and potentially vulnerable to hypothermia, or other homeostatic derangements. The recognition that homeostatic processing may be significantly degraded in these diseases paves the way for developing strategies to ensure that patients are neither subjected to futile diagnostic procedures nor denied medical attention simply because they are uncomplaining.

This study suggests a number of directions for further work. Future studies should engage larger patient cohorts and assess those cohorts longitudinally, to allow more detailed clinical stratification and validate the diagnostic biomarker potential of pain and temperature alterations; ultimately, histopathological correlation will be required. The Alzheimer’s disease group here was relatively young; further work should extend this population to the wider population of older-onset Alzheimer’s disease. Processing of pain and thermal signals should be directly assessed and clinical rating scales should be verified using quantitative sensory testing and other neurophysiological and autonomic techniques and brain mechanisms should be elucidated using parallel functional neuroimaging paradigms. Rather than relying on a simplified binary classification (symptoms present or absent), future work should code symptom frequency and intensity for parametric correlation with other disease measures. It will also be important to explore patients’ conceptualization of interoceptive signals, as this might yield further signatures of disease [for example, delusional elaboration in association with C9orf72 mutations (Downey ); degraded semantic representations of pain, potentially relevant to a number of diseases (Oosterman )]. Pain and temperature may constitute a useful model system for investigating abnormalities of sensory salience, homeostatic and self schema processing that are core to the pathophysiology of canonical neurodegenerative diseases (Craig, 2002, 2009; Downey ; Zhou and Seeley, 2014).